[section:sign_functions Sign Manipulation Functions] [h4 Synopsis] `` #include `` namespace boost{ namespace math{ template int signbit(T x); template int sign (const T& z); template T copysign (const T& x, const U& y); template ``__sf_result`` changesign (const T& z); }} // namespaces [h4 Description] template int signbit(T x); Returns a non-zero value if the sign bit is set in variable /x/, otherwise `0`. [important The return value from this function is zero or /not-zero/ and [*not] zero or one.] template int sign (const T& z); Returns `1` if /x/ `> 0`, `-1` if /x/ `< 0`, and `0` if /x/ is zero. template ``__sf_result`` copysign (const T& x, const U& y); Sets the sign of /x/ to be the same as the sign of /y/. See [@http://www.open-std.org/JTC1/SC22/WG14/www/docs/n1256.pdf C99 7.12.11.1 The copysign functions] for more detail. template T changesign (const T& z); Returns a floating-point number with a binary representation where the signbit is the opposite of the sign bit in /x/, and where the other bits are the same as in /x/. This function is widely available, but not specified in any standards. Rationale: Not specified by TR1, but `changesign(x)` is both easier to read and more efficient than copysign(x, signbit(x) ? 1.0 : -1.0); For finite values, this function has the same effect as simple negation, the assignment z = -z, but for nonfinite values, [@http://en.wikipedia.org/wiki/Infinity#Computing infinities] and [@http://en.wikipedia.org/wiki/NaN NaNs], the `changesign(x)` function may be the only portable way to ensure that the sign bit is changed. [h5 Sign bits] One of the bits in the binary representation of a floating-point number gives the sign, and the remaining bits give the absolute value. That bit is known as the sign bit. The sign bit is set = 1 for negative numbers, and is not set = 0 for positive numbers. (This is true for all binary representations of floating-point numbers that are used by modern microprocessors.) [@http://www.open-std.org/jtc1/sc22/wg21/docs/papers/2005/n1836.pdf C++ TR1] specifies `copysign` functions and function templates for accessing the sign bit. For user-defined types (UDT), the sign may be stored in some other way. They may also not provide infinity or NaNs. To use these functions with a UDT, it may be necessary to explicitly specialize them for UDT type T. [h5 Examples] signbit(3.5) is zero (or false) signbit(-7.1) is 1 (or true) copysign(4.2, 7.9) is 4.2 copysign(3.5 -1.4) is -3.5 copysign(-4.2, 1.0) is 4.2 copysign(-8.6, -3.3) is -8.6 changesign(6.9) is -6.9 changesign(-1.8) is 1.8 [h5 Portability] The library supports the following binary floating-point formats: * IEEE 754 single precision * IEEE 754 double precision * IEEE 754 extended double precision with 15 exponent bits * Intel extended double precision * PowerPC extended double precision * Motorola 68K extended double precision The library does not support the VAX floating-point formats. (These are available on VMS, but the default on VMS is the IEEE 754 floating-point format.) The main portability issues are: * Unsupported floating-point formats. * The library depends on the header `boost/detail/endian.hpp` to determine endianness. * Code such as `#if defined(__ia64) || defined(__ia64__) || defined(_M_IA64)` is used to determine the processor type. The library has passed all tests on the following platforms: * Win32 / MSVC 7.1 / 10.0 / x86 32 and 64-bit, and later Win32 * Win32 / Intel C++ 7.1, 8.1, 9.1 / x86 * Mac OS X / GCC 3.3, 4.0 / ppc * Linux / Intel C++ 9.1 / x86, ia64 * Linux / GCC 3.3 / x86, x64, ia64, ppc, hppa, mips, m68k * Linux / GCC 3.4 / x64 * HP-UX / aCC, GCC 4.1 / ia64 * HP-UX / aCC / hppa * Tru64 / Compaq C++ 7.1 / alpha * VMS / HP C++ 7.1 / alpha (in IEEE floating-point mode) * VMS / HP C++ 7.2 / ia64 (in IEEE floating-point mode) [endsect] [/section:sign_functions Sign Manipulation Functions] [/ Copyright 2006 John Maddock and Paul A. Bristow 2011. Distributed under the Boost Software License, Version 1.0. (See accompanying file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt). ]